Apparatus for controlling the flow of fluids



R. M. RHOADS Filed Oct. l, 1940 APPARATUS FOR CONTROLLING THE FLOW 0F A' FLUID Feb. 23, 1943.

Feb. 23, 1943. R. M. RHOADSv APPARATUS FOR CONTROLLING THE FLOW OF A FLUID Filed Oct. l, 1940 2 Sheets-Sheet 2 EPoX/V,isf/0,9195v Patented Feb. 23, 1943 UNITED STAT ES RTENT 'OF Fil-CE APPARATUS 'FoncoNTRoLHNG THE -FlLoW OF'FLUIDS Roy M. Rhoads, Bel-llower, Calif., assigner o'f one-fourth to `Arthur L. Aimcntrout, onefoui-thto Elwin "B. Hall, 'and one-fourth to Virgil PfBaker, `Los Angeles, Calif. Application October 1, 1940, Serial -No. 359,223

(Cl. 13d-'40) IThis .invention relates to the foontrol of lflowinguid -un'der .pressure Tand .has particular .refieren'celrto `methods andapparatus vfor controlling the low -from Wells- A general object of 'this invention is to provide va practical, effective method and simple dependable land 'eicient lap- `izmira'tus `for `controlling the yflow from .'oil or .gas we1ls,fan'd particularly wells which '.produce water `and other .non-petroleum substances with theioil or gas.

`Itis 'common-'practice to'control flowing .Wells -by'mean`s 'of chokes or 110W beans incorporated in theChristmas tree at vthe head of the Well or installed in the lower portion of the wall. .The chokes or .flow beans of theclass employed to control `the loW from Wells usually embody an oriceof small 'diameter-in thepa'th of t'hewell uidfor bringing "about amarked reduction in the pressure. Such chokes ror'r'low'beans give considerable trouble, lthe 'abrasive solid matter particlesin 'the Well iiuidlquickly enlarging .the orifices 'and necessitating Vfrequent repairs and replacements.

I :have discovered that a iiow kbean often emulsies the oil and water Vof Well. fluid-r passing through it. The emulsions thus `"formedrequire special Acostly treatment to .break them down. Tests have-disclosed :that the uid Within 'a-Well is often unemu-lsied lout nafter vits .passage through the usualfloW-bean-it yisinl the form of an 7emulsion that -i'sY difficult `'to 'break, the flow bean-having acted 'to femulsify the oil and Water produced'theriewithv thus forming a mixture Vthat 'is4 diicult tU-Separate.

Animportantiobjectoi the Apresent invention is lto-piovide a'r'nethod and apparatus -for controlling th'e flow of fluid under pressure, and suited for use-on an oil -Wel1, thatV eiectively reduces the fluid lpressure Withouternulsifying the iluid.

Another object ofithis-invention is toprovide a lowcontrolling apparatus of .the character referred to that -is long wearing and does not require the use of orifice plates, choke nipples and similar parts' that are subject to =rapid wear lby the flow action or abrasive action of the liuid.

Another object of fthisinventionis--to provide a now-controlling 'appz-tratus that produces-'a substantial reduction in th'efluid:pressure-Withy outfav rapid" reduction in the temperature. This feature of the .i invention adapts the apparatus forfthehandling of rniXed-liquidandfgas asproduced by fmany wells, --.and for the lhandling "of A',rnoisturrfz-laden aga-s. YWhen choices flow-beans,

and `other devices having restricted yorices, are employed Vto reduce the pressure vof moisture bearing gases thesudden'reduction in temperayture Vaccompanying 'the'reduction in pressure at the orifice often results Yin freehing the fliquids in the lline thereby choking 01T yor yseriously reducngtheline capacityand necessitating la shut down. In the vapparatus of the present invention there is no Aappreciable reduction in -the temperature of the -uid and,-therefore, no -possibility that liquids 'will freeze in the -line and cause Athe resultant diiculties.

Another object 'of this invention -is to provide `a now-controlling apparatus :adapted to receive `fluidsat-very high pressures andadapted vto re- -ducethe pressure to apoint at 'which the luid may Fbe `safely 'handled by the Astandard pipe lines, separators, etc.

Another object of this invention is to v,provide a 'liow controlling apparatus of .the `character mentioned that is easily reg-ulated'or adjustedfto bring-about the required reductionin pressure. A A further Vobject of thisinvention is to provide a -method for controlling the flow of -uidsirom f -Wells `Which brings about a gradual pressure-re- -longitudinal, detailed sectional View of the apparatus illustrated .in Fig. l. Fig. 3 is .a side elevation of another V-forrn of Ythe apparatus. Fig. 4 is an enlarged Ylongitudinal detailed sectional vew offa portionof the apparatus .shown idF-ig. -3 With-oneof the .110W sections or .un'its appearing inside elevation, `andl-liigfB is =a --side elevation of another form of `apparatus Iofthe invention.

The embodiment of the invention illustrated -infFigs.-1-and 2=of the-drawings may besaid to comprisefgenerally, aplurality of ovv-.sections orlflow units lil, |l, l2, -l3 .and l, together formi-nga viluidconductor or carrier of gradually .increasing fluid capacity vfor handling orconducting thefluid from the well.

The form of the invention illustrated in Figs. l and 2 of the drawings and the method of the invention practiced with this apparatus involve the employment of a plurality of flow sections or units Il] to I4, inclusive, nested or telescoped one within the other to occupy a minimum of space. The invention contemplates the formation and assembling of the units I9 to I4 in such a manner that the apparatus may be installed in the wall, for example connected in the oil string or production string adjacent the lower end of the same. In the particular application of the invention illustrated the assembly of the sections IIJ to I4 is connected with a Christmas tree part or well head I5, being interposed between the part or head I5 and a pipe I5 for conducting the fluid from the well. It is to be understood that the equipment may be connected in the flow line from the well at any other point, as desired.

The flow section or unit I constitutes the rst or inner fluid handling element and, as illustrated, may be directly attached to the well head I5. In the particular embodiment of the invention illustrated the inner or lower end of the unit I9 is provided with a flange I6 secured to the well head I by bolts or screws I'I. The fluid handling section or unit IEI extends outwardly or upwardly from the head I5 and is formed with an external shoulder I8 spaced from the head. The flow sections or units IIJ to I4 are elongate tubular members telescoped or nested one within the other in spaced substantially concentric relation to provide a tortuous passage of gradually increasing fluid capacity, as will be more fully described. In this telescoped or nested assembly of tubular elements the unit I9 constitutes the innermost part and the unit I4 the outermost part, and the invention provides means for holding the several flow sections or units in the nested relation. This means includes a plate or ring I9 arranged around the inner unit I0 to bear on its shoulder IS. The ring I9 may be fixed and sealed to the unit II) as by welding. The sections or units I2 and I4 have their inner or lower ends 1 secured to the ring I9. In practice the ends of the sections I2 and I4 may be received in annular grooves in the ring I9 and welded or otherwise xed to the ring.

The means for holding the units I0 to I4 in the nested or telescoped relation further includes a plate 2I applied to the upper or outer ends of the units II and I3. The plate 2I is a disclike imperforate member forming a partition or closure at the outer ends of the units II and I3. I

A central recessed or socketed boss 22 may be formed on the under side of the plate 2I to fit in the end portion of the unit II and the outer end portion of the unit I3 may be received and fixed in an annular groove 23 in the periphery of the plate 2I. A tubular adapter or carrier 24 supports the llow sections or units II and I3 and couples the apparatus with the pipe I5. 'Ihe carrier 24 may be a length of pipe or the like and is arranged to engage or telescope over the A suitable packing gland 25 is ing gland 26 is provided on the pipe I to seal about the carrier 24. Circumferentially spaced spokes or webs 3l extend between and connect the flow unit I3 and the carrier 24 whereby the carrier supports the units II and I3 and the plate 2 I.

The invention provides means for shifting or adjusting the carrier 24 to vary or change the disposition of the flow units II and I3 relative Vto the flow units I0, I2 and I4, to regulate the pressure-reducing action of the apparatus and thereby control the flow from the well. Aligned lugs 2I and 23 are provided on the carrier 24 and the pipe I6, respectively. The lug 21 may be a projecting part of a collar 29 welded or otherwise xed to the carrier 24 and the lug 28 may extend from a bell or enlargement on the pipe I6. The lug 2`I is formed with a longitudinal or vertical opening 39 and the lug 28 has a somewhat smaller opening 3| aligned with the opening 39. An adjusting screw 32 is threaded in the opening and is provided with a reduced unthreaded portion 33 which is rotatable in the opening 3l. A shoulder 34 and a collar 35 on the screw 32 cooperate with the upper and lower sides of the lug 28 to hold the screw against longitudinal movement. The projecting upper portion 36 of the screw 32 is formed for engagement by a turning tool such as a wrench, for example, it may be polygonal, as illustrated. Rotation of the screw 32 adjusts or moves the ilow sections II and I3 vertically or longitudinally with respect to the fixed flow units I0, I2 and I4.

With the apparatus of the invention installed as above described, the passage or opening 33 extending through the innermost flow unit I0 forms a lluid duct leading from the interior of the flow pipe or well head I5. The passage 38 in the unit I9 may be considerably smaller in diameter than the head I5, or the fluid conductor delivering the fluid from the well, to provide for an initial fluid friction action with a proportionate reduction in the pressure. This relation of the passage or opening 38 to the fluid source or well head I5 is not essential though probably .desirable in most installations. The passage or opening 38 in the unit I9 extends outwardly or upwardly to a chamber or space 39 defined by the outer portion of the unit I0 and the plate 2 I.

As mentioned above, the plurality of ow units I9 to I4 are in spaced relation to leave or provide for an elongate continuous duct or passage for controlling the pressure of the owing well fluid. This duct or passage extends from the chamber or space 39 to the interior of the carrier 24 and is of peculiar or special formation. In accordance with the invention the relationship or spacing of the flow units I0, II, I2, I3 and I4 is such that the pressure controlling duct or passage gradually increases in fluid capacity to control the fluid flow in accordance with the method of the invention.

The ilow unit II telescoping over or partially surrounding the unit I 0 is spaced from the exterior of the unit I 0 to leave an annular space or passage A of restricted cross-sectional area or fluid capacity. The outer end of this reduced passage A is in communication with the chamber or space 39 to receive the fluid under pressure issuing from the opening 33. The inner or lower end of the flow unit II is spaced from the ring I9 leaving an annular chamber or space l40 and the lower end of the passage A joins this space. The cross-sectional area or fluid l42. 'sage C is larger in crosssection'al area or 'fluid capacity of the passage A utaxation ressa/1an that of the passage or openin'g'38 and in a typical embodinie'nt of the invention 'the "passage A is of lsubstantial length. The greatly restricted elongate 4passage A operates to markedly reduce the pressure of the fluid Ypassing through it.`

The flow unit I2 extending outwardly or upwardly from the ring I9 is arranged to have its interior surface spaced from the external surface of the yflow unit I'l to provide or leave an annular fluid passage B. The upper or outer end of the unit I2 is spaced from the plate 2'! so that an annular chamber or space 4|, defined by the sections Il and I3 rand .the plate 2|, is

left at the outer rend 'of the passage B. The

The differential in capacity or size of the passages A and B may vary in different installations. Although the passage B is somewhat larger in fluid capacity than the passage A itis still quite restricted or limited in fluid capacity to control the pressure and now. The passage B is 'an elongate restricted opening or duct that produces a marked reduction in the pressure on the fluid passing through it. Thus the passage B `provides Vfor a continued substantial reduction in the pressure of the fluid while maintaining a substantially constant fluid ow rate.

The flow unit I 3 projecting inwardly or'downwardly from the plate 2| is proportioned and arranged to telescope over the unit I2 with clearance providing or leaving a fluid passage C. The passage C extends inwardly or downwardly 'from the space "4I to the lower end of the unit I3. The lower end vof the unit I3 is spaced from the ring I to leave an annular chamberor space 42 which is dened by the units `I2 and i4 and the ring 19. The passage C yserves to conduct the fluid from the space '41 to Vthe space In accordance with the invention thejpastheror continued reduction Ain the pressure of the fluid while lmaintaining substantially the same ow rate. Accordingly, the iluidat the space 42 is at a lower pressure than at the space il but is owing at about the vsance rate.

The outer flow section or unit f4 which ex tends outwardly or upwardly from the ring 19 telescopes over the unit I3 withclearance providing or leaving an annular space or passage D. The passage D extends outwardlyironi the space 42 to the interior of the carrier 24 `an d forms the outer portion o f the flow controlling d uct o f the invention. The p:tissage lllmisdsnaewhat larger Vin crpss sectionalgareapr iluid c a ,paoity `their the Passage .-.Hswever as .illustrated, the passage D is oflimitedilui'd capacity 75 so that .the uidrlg'sn'gzthiqgsh this ilerraduct afar-lied antistante-11rd. and its pressure, its reduced while 'its volume ismaptairred, M lt yg/ in baseert that the `pressure dattieattic issuing from the outer end of thepas'sage D "isjfconsid- 'erably -less than the pressure at fthe `lower jend 'of the passage and 'it will be apparent that 'the rate'ofiilow'ismaintained c Tcheressages 'Af-*BL-Cwnstiti. a 10aa -`continuous restricted flow `and pr-:estire controlling j canal, 'conduit -or duct whichgradually increases in volume or fluid 'capacity fromitsfintake, end te its cutleitjend- This loris rsst'fict'ed gradually 'enlarging duct A- B-"C-Doperatesfto 'gradually decrease the vpr essi ire of the huid While maintaining 'a substantially constant rate Aof flow. lIfhe Control duct 'A-"B'- C-' D reduces thejiluid ypressure to such `anjextent that nitfis operable to 'bring a very high dangerous pressuredownto a point where thelluidgnay Abe'safely `and'readily handled by standard piping. etc, The control 'duct A+B- C-D of theinvention `serves to reduce the Iluid pressure as required without `emulsifying the 'oil f and the water particles lsuspended therein and without causing Ia sudden pressure drop with the accompanying temperaturedrop which Voften occurs in other now controlling Ldevice.

The assembly offthe 1units 1Mito I'4, inclusive, 'providing or defininig'the long, restricted, gradually increasing vduct "A-'BLC-D iconstitutes van 'efficient fluid pressure and 'volume controller. This `pressure controllerjs regulated 'by means of the screw 32 "and is, 'in' effect, adjustable pressure and volume regulator. When thefsc'reyvf32 is threaded to move Jthe Vo ai'rrie'rjz'tl and `the/units H and V`I3 Youtwardly o r 'upwardlyjthe effective lengths of the passages l'A-*B 'C Dare reduced so 'that the "control ductreduces `the pressure `-to a less'degree. When thes'crewaZ 'operated to shift the carrier 24 and thesectiops 1 -an d manwardly orfdownwardl'yfthe lengths 'of therestricted effective portions of the passages `A-'B;CLD Vare 'increased "so that tliejcontrol duct reduces the fluid pressure to agreater *extent.

Pressure indicating means lmay be associated with the vflow controller or regulatort'o indicate the pressure conditions'in various parts of fthe apparatus. Pressure gauges'44 ymay be mounted on lthe units VI0 and l4and'on Atheca'rrier 24 to indicate the pressures 'inthe' spaces' 40542 andf4'l respectively. A port "45fin'ay be vformedV in wthe shouldered portion of the'unit litoinaintainthe gauge of that unit 'injcornniunicati'onwith the space 4E). The Vgauge'4!4 forfth`e space ^42 may have its pipe or ttiiigv arranged in an opening or port 46 in the wall ofthe unit I4 to `directly communicate with the space V4.2. The `rgauge "44 for the space 4l may have'itspipe or'ttin'g'communi'cating with a port 41 Which'pa'ssesthrough thewall ofthe carrierf'24, oneof'thewe'bsBTand jthewau ofthe unit 3 vte thedspaca t2.A Iftdesired a pressure gauge 48'n`1ay'leprcpvitiedonY the Well head l5 to indicatethe'initial iluidpressure and a pressure gauge `49'1vfria .`5 fv be'providedionjthe carrier 24 to indicate the nalpressure'in the carrier and pipe T6. When adjusting thefljow controlling Vapparatus by 'means of 'the lscrew-32 the gauges 44, 48 and 49 may be consulted' to facilitate the desired setting or regulationof the apparatus.

'ligs. 3 vanda of the drawings illustrate an'apparadis "o fithe inventipninwmh a piurautyof flowcntrolling'sections 'or`units 10a, 'I la, '12,

being understood that the length and fluid capacities of the flow units may vary with diierent installations. The units IIli to I4a are gradually increased in size or uid capacity from one end of the assembly or series to the other, the unit IIla forming the element of smallest fluid capacity at the inlet end of the series and the unit I4a forming the element of largest fiuid capacity at the outlet end of the series. In most installations the cross sectional area or fluid capacity of the unit Il)a is much less than that of the well head I5 or the pipe conducting fluid to the unit, and the largest unit I4"l is likewise considerably smaller in uid capacity than the head I5.

The adjacent ends of the flow units Illbl to I4 are connected for the passage of the fluid. In

the typical arrangement illustrated the sections Ille to I4@ are arranged in longitutdinal alignment with their adjacent end parts in telescoping relation. The unit I0EL has its upper end portion received in the lower end of the unit IIa, the

upper portion of the unit II8L is received in the lower portion of the unit |28, the upper part of the unit I2a is received in the lower portion of the unit |39', and the upper part of the unit I3a is received in the lower end of the uppermost unit |45. Where the apparatus is to be regulable or adjustable the adjacent sections or units slidably or shiftably t one in the other and packing glands are provided to seal between the slidably fitted parts. While I have shown the assembly of units I IP- to I4a extending straight from the well head |5 it is to be understood that the structure or assembly may be disposed in other manners, for example, it may be arranged toy extend at an angle from the head, in which case a suitable fitting is employed to connect the inner end of the unit I Ia with the Well head I5.

The flow units II)a to I4a interposed between the well head I5 and the pipe I6, as above described, constitute a long, continuous restricted through the sections Illa to I4a is maintained substantially constant by reason of the gradually increased fluid capacity of the assembly. The fluid passing through the units IIIa to I4a is not subjected to a sudden change in velocity, direction or temperature, and is not emulsified or subjected to undesirable low temperatures. Suitable pressure gauges 56 are connected in the sections or units |Ilfi to I4il to indicate the pressures in the various parts of the assembly. A gauge 56 may be provided intermediate the ends of each unit Ille to 14B.

The total length of the flow controlling assembly Il)a to |4 may be varied to change or regulate the pressure reducing action of the apparatus.

The pipe I6 may be moved relative to the well head I5 to vary the length of the restricted flow controlling assembly ||Ia to |421. The variation in length of the assembly may be substantially equally distributed throughout the length of the assembly to evenly vary the pressure reducing action of the assembly throughout the length of the apparatus. On the other hand, if desired, the adjustment or regulation may be confined to one unit by shifting such unit relative to the other units, or may be confined to a selected number of units to vary the pressure reducing action at given sections of the apparatus. It Will be seen that a reduction in the length of the assembly liln to |4, whether it be distributed or not, lessens the pressure reducing action of the apparatus while an elongation of the assembly increases the pressure reducing action. The regulation obtained by contraction or elongation of the assembly II]a to |4a may be determined by consulting the gauges 56.

Fig. 5 of the drawings illustrates a form of apparatus of the invention embodying a plurality of ow sections or units Ib, IIb, I2", I3b and I4b, forming a gradually enlarging elongate pressure and volume controlling conduit and this form of the invention is characterized by controllable by-passes connected between spaced parts of the assembly to vary the pressure reducing action of the apparatus.

The flow controlling sections or units IIIb to I4b form a conduit or fluid conductor to be interposed between the well head I5 and the pipe I6. While the sections Illb to |4D may be disposed and related in various manners I have shown them in spaced, generally parallel relation. It is to be understood that the invention is not to be considered as restricted to this particular arrangement or disposition of the flow units IIJb to |41. The units II)b to I4b are varied or graduated in fluid capacity to constitute a long, fluid conduit of gradually increasing capacity. The unit IIlb constitutes the inlet element of the assembly and is the smallest or most restricted in fluid handling capacity and the unit I4b is the outlet or discharge element of the assembly and has the largest fluid capacity. The sections or units I0b to I4b may be increased in fluid capacity in a regular progression or in an irregular progression, as desired. Assuming that the units ID and I4b are positioned vertically the upper end of the unit I6b is connected with the upper end of the unit IIb by a connecting pipe 60 extending between elbows or fittings 6I on the ends of said units. The pipe 60 may be quite short and may be of the same diameter as the unit Illb or may be of the same diameter as the unit IIb. The lower end of the second unit I Ib is connected with the lower end of the third unit I2b by a connecting pipe 62 carried by ttings 63 on the ends of said units. I have shown the pipe 62 of the same diameter as the unit I2b, it being apparent that it may be of the same fluid capacity as the unit IIb. The upper ends of the units I2b and I3b are connected in fluid transferring relation by a pipe 64 extending between suitable ttings 65 on the ends of said units. The pipe 64 is of suitable diameter, for example, it may be of the same diameter as either of the adjacent units. The lower end of the unit I3b is connected with the lower end of the unit I4b by a connecting pipe 66 extending between suitable fittings 61 on the ends of the units. The pipe 66 may be of the same diameter as the unit I4". A suitable reducer or adapter 68 may serve to connect the outer or upper end of the unit |41 with the pipe I6. It will be seen that the units |01 to |41 assembled as just described form a longy continuous pressure controllingV pipe which tapers or gradually increases in fluid capacity to gradually and uniformly reduce the pressure on the fluid passing therethrough while maintaining a substantially constant rate of fiuid flow.

The regulating means or adjusting means in the apparatus illustrated in Fig. 5 is in the form of valve controlled by-passes for cutting in and cutting out-certain parts of the tapered or gradually enlarging fluid conduit |01 to |41. The regulating means may comprise one or more bypasses connected between selected ow units |51 to |41. In the case illustrated there are two bypasses B9 and '19. The by-.pass S9 is arranged to cut off or by-pass uid past the units |21 and |31 while the by-pass 'l0 is arranged to Icy-pass fluid around portions of the units |21 and |31. The by-pass 69 may be in the form of a ypipe or fluid conductor connected between the fittings 63 and 61 on the lower ends of the units |21 and |31. The by-pass 69 is proportioned to adequately handle the uid flow. A valve 1| is connected in the by-pass 69. When the valve is closed the fluid is obliged to pass through the units |21 and |31. When the valve 1| is open the fluid may pass directly from the pipe 62 to the pipe 66 and thus iiows from the unit l1 to the unit |41 without passing through the units |21 and |31. The by-pass 'I9 may be a suitable pipe or conduit whose ends are connected in fittings 'l2 in the units l21u and |31. The fittings 12 may be connected in the units |21 and |31 at any selected points so that the by-pass 'lll is operable to cut out selected portions of the units. The by-pass l0 is equipped with a valve 13. Assuming that both valves 'H and. I3 are closed the fluid is obliged to ow completely through both units |21'z and |31. With the valve 7| 4closed and the valve 13 open the fluid by-passes the upper or outer portions of the units |21 and |31.

Suitable pressure gauges 'I4 are connected in the units |61 to |41 or in the ttings associated with the units. In the case illustrated there is a pressure gauge 'M connected in the fitting at the outer or down-stream end of each unit |01 to |41. The gauge 'M at the down-stream end o-f the unit |41 may be connected in the adapter 68. A presf sure gauge 'l5 may :be Iprovided on the well head 5. It will be seen that the valves 1| and 13 may be utilized to vary the effective length of the tapering or gradually increasing uid conductor to regulate the pressure reducing action of the same. The pressures in the various parts of the -apparatus and the results of the said regulation may be ascertained by consulting the pressure gauges 1t.

In eac'n form of the invention the size or fluid capacity of the passage gradually increases substantially in proportion to the increase in fluid volume, which results from the gradual reduction in pressure, thus providing for a substantially uniform fluid ow rate throughout.

Having described only typical preferred forms and applications of my invention, I do not wish to be limited or restricted to the specic details herein set forth, but wish to reserve to myself any variations or modifications that may -appear to those skilled in the art, or fall within the scope of the following claims.

Having described my invention, I claim:

l. Apparatus for controlling the flow of a fluid which increases in volume when subjected to -a pressure drop, comprising an unobstructed conduit connected to a well or other source of uid under pressure, the uid carrying capacity of the conduit being so proportioned to the pressure head and the viscosity of the fluid as to permit fluid at a predetermined gravimetric rate to pass through the conduit at a predetermined approximately uniform velocity, the cross sectional area of the conduit increasing in the direction of flow to accommodate the increasing volume of the iiuid whereby the Ipredetermined velocity is maintained approximately uniform throughout the conduit.

2. Apparatus for controlling the flow of a which increases in volume when subjected to a pressure drop, comprising an unobstructed conduit connected to a Well or other source of fluid under pressure, the cross sectional area of said conduit increasing in the direction of flow to accommodate the increasing volume of the uid, said conduit being so proportioned to the pressure head, the viscosity of the fluid and the changing volume of the fluid as to cause fluid at a predetermined gravimetric rate to pass through the conduit at a predetermined approximately uniform velocity throughout the length of the conduit whereby the Volume of fluid discharged at the outflow end of the conduit and the pressure of the fluid thereat are controlled.

3. Apparatus for controlling the flow of a fluid which increases in volume when subjected to a pressure drop, comprising two or more tubular units assembled to form an unobstructed conduit connected to a well or other source of uid under pressure, the fluid carrying capacity of the conduit being so proportioned to the pressure head and the viscosity of the liuid as to `permit fluid at apredetermined gravimetric rate to pass through the conduit at a predetermined approximately uniform Velocity, the cross sectional area of the second and each subsequent unit in the direction Aof iiow' being sufficiently greater than the cross sectional area of the preceding unit to accommodate the increasing volume of the fluid whereby the predetermined velocity is maintained approximately uniform throughout the length of the conduit.

4. Apparatus for controlling the flow of a fluid which increases in volume when subjected to a pressure drop, comprising an unobstructed conduit connected to a well or other source of fluid under pressure, said conduit being composed of two or more connected tubular units, the cross sectional area of the second and each subsequent unit in the directionV of flow being greater than the cross sectional area of the preceding unit to accommodate the changing volume of the fluid, said conduit being so proportioned to the pressure head,` the viscosity of the fluid and the changing Volume of the uid as to permit fluid at a predetermined gravimetric rate to pass through the conduit at a predetermined approximately uniform velocity whereby the volume of uid discharged at the outflow end of the conduit and the pressure of the fluid thereat are controlled.

5. Apparatus for controlling the flow of a fluid which increases in volume When subjected to a pressure drop, comprising an unobstructed conduit connected to a Well or other source of fluid under pressure, said conduit consisting of connected sections, the cross sectional area of each trailing section being larger than the cross sectional area of the preceding section to accommodate the changing volume of fluid, each section being so proportioned'to the pressure head, the viscosity of the fluid and the changing volume of the fluid as to permit fluid at a predetermined gravimetric rate to pass through all of the sections at a predetermined approximately uniform velocity whereby the volume of fluid discharged at the efiluent end of the conduit and the pressure of the fluid thereat are controlled.

6. Apparatus for controlling the flow of a fluid which increases in volume when subjected to a pressure drop, comprising an unobstructed conduit connected to a well or other source of fluid under pressure, said conduit being composed of two or more connected tubular units, the cross sectional area of the second and each subsequent unit in the direction of flow being greater than the cross sectional area of the preceding unit to accommodate the changing volume of the fluid, said conduit being so proportioned to the pressure head, the viscosity of the fluid and the changing volume of the fluid as to permit fluid at a predetermined gravimetric rate to pass through the conduit at a predetermined approximately uniform Velocity whereby the volume of fluid discharged at the outflow end of the conduit and the pressure of the fluid thereat are controlled, at least one of the tubular units being telescopically arranged in another tubular unit and movable with respect thereto to vary the effective length of the conduit.

7. Apparatus for controlling the flow of a fluid which increases in volume when subjected to a pressure drop, comprising an unobstructed conduit connected to a well or other source of fluid under pressure, said conduit being composed of two or more connected tubular units, the cross sectional area of the second and each subsequent unit in the direction of flow being greater than the cross sectional area of the preceding unit to accommodate the changing volume of the fluid, said conduit being so proportioned to the pressure head, the viscosity of the fluid and the changing volume of the fluid as to permit fluid at a predetermined gravimetric rate to pass through the conduit at a predetermined approximately uniform velocity whereby the volume of fluid discharged at the outflow end of the conduit and the pressure of the fluid thereat are controlled, at least one of the tubular units being telescopically arranged in another tubular unit and movable with respect thereto to Vary the effective length of the conduit, and means for controlling the movement of the movable member of the telescopic unit.

8. Apparatus for controlling the flow of a fluid which increases in volume when subjected to a pressure drop, comprising an unobstructed conduit connected to a well or other source of fluid under pressure, said conduit consisting of connected sections, the cross sectional area of each trailing section being larger than the cross sectional area of the preceding section to accommodate the changing volume of fluid, each section being so proportioned to the pressure head, the viscosity of the fluid and the changing volume of the fluid as to permit fluid at a predetermined gravimetric rate to pass through all of the sections at a predetermined approximately uniform velocity whereby the volume of fluid discharged at the eflluent end of the conduit and the pressure of the fluid thereat are controlled, and valved means for by-passing the fluid from one of said sections to another around at least one section whereby the effective length of the conduit may be decreased.

9. Apparatus for controlling the flow of a fluid which increases in volume when subjected to a pressure drop, comprising tubular flow units positioned one within the other in spaced relation so that the space between adjacent units forms an unobstructed fluid passage which increases in cross sectional area to accommodate the changing volume of fluid and is so proportioned to the pressure head, the viscosity of the fluid and the changing volume of the fluid as to permit fluid at a predetermined gravimetric rate to pass through the passage at a predetermined approximately uniform velocity whereby the volume of fluid discharged at the eflluent end of the apparatus and the pressure of the fluid thereat are controlled, means for connecting the passage to a well or other source of fluid under pressure, means for supporting one unit for axial movement with respect to the other unit and means for moving the movable unit to vary the effective length of the passage.

l0. Apparatus for controlling the flow of a fluid which increases in volume when subjected to a pressure drop, comprising a group of tubular units arranged one within the other in spaced relation, a second group of tubular units arranged one within the other in spaced relation, said groups being so nested that the units of the two groups surround one another in spaced relation to form a continuous unobstructed duct so proportioned to the pressure head, the viscosity of the fluid and the changing volume of the fluid as to permit fluid at a predetermined gravimetric rate to flow through the duct at a predetermined approximately uniform velocity whereby the Volume of the fluid discharged at the outflow end of the duct and the pressure of the fluid thereat are controlled, means for connecting the duct to a well or other source of fluid under pressure, and means for shifting one of said groups with respect to the other to change the effective length of the duct.

ROY M. RHOADS. 

